Method of lighting intensity automatic adjustment and device with lighting intensity automatic adjustment

ABSTRACT

Method of lighting intensity automatic adjustment and corresponding device, in which the light emitted by a light unit is adjusted according to the input signal from a passive infrared motion sensor and/or a dusk sensor. In one embodiment, starting from a stand-by condition in which the lamp unit is switched-off, the light from the lamp unit is smoothly brightened up to 100% of its maximum power in case of detection of a motion from the motion detector and in case that also a dusk condition is detected by the dusk sensor.

FIELD OF THE INVENTION

The present invention relates to the method of lighting intensity automatic adjustment as well as to device with lighting intensity automatic adjustment, especially such devices as high-pressure (mercury—discharge lamps, sodium discharge lamps, metal halide lamps) or low-pressure (fluorescent lamps) discharge lamps, energy-saving lamps as well as lamps and light bulbs with LEDs. Such devices are designed for lighting staircases, corridors, passageways in buildings, offices, cellars etc., and can have any form, for example—panels, lighting strips, wall lamps, ceiling lamps, embodied lamps etc.

BACKGROUND OF THE INVENTION

The solutions of staircases', passageways', rooms', cellars' lighting based on traditional incandescent bulbs or fluorescent lamps, switched on by conventional circuit-breakers and equipped with time-lag switches, turning the lights off after a pre-set time, regardless of whether the user or users need such lighting or not—are commonly known. Another drawback of such solutions is the need to install multiple switches and connect them by electric wiring with power line supplying light sources.

The solutions of staircases', corridors', passageways' and cellars' lighting based on traditional lamp with an external motion sensor and time-lag switch, turning the lights off after a pre-set time, regardless of whether the user or users need such lighting or not are also commonly known. The advantages of these solutions consist in eliminating the need of searching for circuit-breaker in a dark room as well as lower power consumption compared to no motion sensor lighting (for example—nine times lower). The inconvenience of these solutions is, that due to the high working temperature of traditional light-bulbs requires the motion sensor to be installed not closer than 0.5 metres from them, which causes high costs of equipment, due to high installation costs. Another important drawback consists in frequent need to exchange light-bulbs, due to their short life in continuous switching on and off cycles. Another inconvenience leading to installation costs increase is the need to mount motion sensors at all entrances or on each floor. The aim of the present invention is to develop a method of lighting intensity automatic adjustment ensuring at the same time highest flexibility and efficiency of the system as well as the energy saving and extension of life of light emitting elements.

SUMMARY OF THE INVENTION

The object of invention has been achieved by development the method of lighting intensity automatic adjustment, working as follows—after connecting device to supply network, the minimum value of feeding voltage parameters, allowing the electronic control system as well as motion and dusk sensors to remain in “stand-by” mode, is set-up, then, sensors are synchronized with electronic control system, both—value of output signal generated by motion sensor and activating cycle of device's working mode, and value of output signal generated by dusk sensor at which the voltage provided to the light source increases to its maximum value—are set-up in the electronic system, and during programmed lighting time the light source emits light with full 100% power, time of light emitting and voltage decrease time, in which voltage provided to the light source decreases smoothly to the minimum power value—are also set-up in the electronic system—the light source does not emit light and the device passes into “stand-by” mode, therefore after setting-up all values, the device is left in “stand-by” mode and sensors remain in “stand-by” mode too, further device is activated automatically when a movement is detected by the motion sensor and its signal is transmitted to the unit, which compares signal generated by the motion sensor with signal generated by dusk sensor, as well as with value being previously set-up, i.e. it checks whether the minimum admissible natural lighting level is exceeded or not—if it is darker, the system increases voltage of light source feeding to the maximum value—the device emits light with full 100% power and keeps it within the pre-set period of time, then after this pre-set period of time expired the system checks whether the motion sensor still generates a detection signal, if so—voltage provided to the light source is kept at its maximum level, if not—voltage provided to the light source is reduced to its minimum value, and the device passes into “stand-by” mode—the device does not emit light.

Advantageously the voltage provided to the light source is increased to the maximum value, the light source emits light with full 100% power, or is reduced stepwise.

Advantageously the voltage provided to the light source is increased to the maximum value, the light source emits light with full 100% power, or is reduced smoothly.

The aim of invention also has been achieved by elaborating a method, working as follows—after connecting device to supply network, the minimum value of feeding voltage parameters, allowing the electronic control system as well as the motion sensor to remain in “stand-by” mode is set-up, then, the motion sensor is synchronized with electronic control system, the value of output signal generated by motion sensor and activating working cycle mode of device, time of voltage increase, in which voltage provided to the light source increases smoothly to the maximum value within a pre-set time, time of emitting light by the light source with full 100% power, time of voltage decrease, in which voltage provided to the light source decreases smoothly to the minimum power value within a pre-set time are also set-up in the control system, the device passes into “stand-by”mode, the light source emits light with minimum power, therefore after setting-up all data, the device is left in “stand-by” mode—the light source emits light with well-defined minimum power, and the motion sensor remains in “stand-by” mode; then, when a movement is detected by the motion sensor, the system increases smoothly the voltage of light source feeding to the maximum value—the device emits light with full 100% power and keeps it within the pre-set period of time, then after this the pre-set period of time expired the system checks whether the motion sensor still generates a detection signal, if so—voltage provided to the light source is kept at its maximum level, if not—the device passes into the “stand-by” mode, voltage is reduced smoothly—the device emits light with well-defined minimum power.

Advantageously the device is additionally equipped with a dusk sensor and therefore the additional data about required minimum lighting intensity of environment are set-up in the electronic system, and below this level the device passes from “stand-by” to working mode, and when a movement is detected the respective signal is transmitted by the motion sensor, the lighting intensity of environment is measured, the signal coming from the dusk sensor is compared with the value pre-set for device activation and transmission of signals switching on or off the light source feeding.

Advantageously the device is additionally equipped with a time measuring unit, which is synchronized with motion sensor and electronic control system; the additional value, i.e. time of working in reduced power mode is set-up in the electronic system; after terminating working with full power, the light source emits lights with a limited power—following signal coming from the motion sensor, and it waits for further motion sensor's signal—in case of its lack, the device passes into the “stand-by” mode, in case the signal is transmitted—into 100% working mode.

The aim of invention also has been achieved by elaborating a device with lighting intensity automatic adjustment, which contains containing a feeding converter having clamps directly connected to the supply network, composed of the following elements, connected in series EMI perpetual conduction interference filter, rectifier with passive power factor correction system PPFC, reducing distorsions of current absorbed from the supply network, PWM controller of MOSFET together with MOSFET power transistor and PWM-MOS safety system, pulse transformer TR, rectifier with an output filter (RC) and feedback block, stabilizing the output current/output voltage CC/CV, the feedback block outputs are connected to the light source—LEDs, through a galvanic separator of feedback circuit (OPTO), to the input of PWM controller of MOSFET power transistor and MOSFET power transistor PWM-MOS as well as to the feeder ZKPIR of motion sensor controller KPIR, connected to the motion sensor PIR output, and—through the output current regulator RPW—to the feedback block, stabilizing the output current/output voltage CC/CV of rectifier with an output filter RC and pulse transformer TR, which are interconnected, and—through the galvanic separation of feedback circuit OPTO—to the MOSFET power transistor PWM controller as well as to MOSFET power transistor and safety system PWM-MOS, whilst the assignment of motion sensor PIR consist in detecting movement of objects within motion sensor PIR range and then to transmit information about detected object to the output current regulator RPW, which signal from the passive infrared sensor PIR is amplified, and then, it is processed by the sensor controller KPIR, controlling the output current switch output current regulator RPW, which allows a smooth brightening of the light source within the required, pre-set time, and when the movement stops, the controller KPIR additionally keeps the output current regulator RPW switched on within precisely determined, programmed period of time, and after that, the output current regulator RPW is being switched off, turning the lights down to the well-defined power, the power provided to the controller KPIR is realized through the feeder ZKPIR, supplied directly from the converter, feeding the light source, and the output current regulator RPW function consists in reducing smoothly the current passing through the light source, so that the power decreases and system works in limited power consumption mode, or in increasing smoothly the current passing through the light source, to the maximum value.

The aim of invention also has been achieved by designing a device with lighting intensity automatic adjustment, which contains a motion sensor PIR fed with supply network power, the function of which consists in detecting movement of objects being within the range of the motion sensor PIR, and then to switch on the load connected to the module MPO of the light source feeder, which signal generated by motion sensor PIR is amplified, and then it is processed by controller KPIR controlling switching on the module of the load change-over MPO, said switching on this module MPO means, that voltage from supply network is provided to the clamps of feeding converter, which is composed of perpetual conduction interference filter EMI, rectifier with passive power factor correction system PPFC, reducing distorsions of current absorbed from supply network, PWM controller of MOSFET power transistor together with MOSFET power transistor and safety system PWM-MOS, pulse transformer TR, rectifier with an output filter RC and feedback block, stabilizing the output current/output voltage CC/CV—all this elements connected in series, in case, if the controller KPIR, basing on signals received from sensor's detector PIR discovers a motion switched on the module MP—and thus, the converter—and remains so, until motion is being detected, in case the motion stops, the controller KPIR additionally keeps the module MPO switched on within precisely determined, programmed period of time and after that, the module MPO is being switched off, cutting off supply of the converter's circuit, whilst the module KPIR is supplied with power through the feeder ZKPIR providing constant voltage of required pre-set parameters to the controller KPIR and the current has power level, allowing to proper control of the module MPO, and is equipped with a time measuring unit UOC, connected to the controller KPIR, said controller KPIR if no motion is detected by the motion sensor PIR, transmits a signal to the time measuring unit UOC, which begins to count down the time, and after a pre-set period, time measuring unit UOC transmits such information to the output of current regulator RPW, which reduces smoothly the current passing through the light source, and thanks to that, the device works in limited power consumption mode, whilst during working in this mode—the motion sensor PIR detects a movement, the time measuring is reset, and output current regulator RPW increases smoothly the current passing through the light source to the maximum value, while in case when no movement is detected by motion sensor PIR working in limited power consumption mode and the pre-set time is counted down, the time measuring unit UOC transmits the respective signal to the module MPO, which disconnects network voltage from converter and all remaining units start working in “stand-by” mode.

Advantageously the device is equipped with a dusk sensor CZ, connected directly to controller's KPIR input, which function of consists in detecting the environment day-light intensity within the range of the dusk sensor CZ, when the light intensity is insufficient and switching on the artificial lighting is necessary, and then—in transmitting such information to the controller KPIR in which the information is processed and compared with the required, pre-set value and then, the module MPO—and thus, the converter—is switched on by the controller KPIR and remains so, until the motion is being detected and light intensity remains insufficient, or—it is switched off and remains so, when the light intensity is too big.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject of invention is shown in drawings where

FIG. 1 shows the block diagram of lighting intensity automatic adjustment method, according to the invention, in an advisable execution example,

FIG. 2 shows the block diagram of of lighting intensity automatic adjustment method, according to the invention, in an alternative advisable execution example,

FIG. 3 shows the block diagram of of lighting intensity automatic adjustment method, according to the invention, in other following advisable execution example,

FIG. 4 shows the block diagram of lighting intensity automatic adjustment method in an advisable execution example,

FIG. 5 shows in general outline the device with lighting intensity automatic adjustment, according to the invention, in an advisable execution example,

FIG. 6 shows in general outline the device with lighting intensity automatic adjustment, according to the invention, in the second alternative advisable execution example

FIG. 7 shows in general outline the device with lighting intensity automatic adjustment, according to the invention, in the third alternative advisable execution example.

DETAILED DESCRIPTION OF THE INVENTION

A block diagram of lighting intensity automatic adjustment method, according to the invention, in the simplest execution example is shown in FIG. 1. In this option, the device with lighting intensity automatic adjustment contains an electronic control unit, a light source, motion and dusk sensors. The essence of the method is that after connecting the device to the supply network the parameters of minimum feeding voltage value, allowing the electronic control unit as well as the motion and dusk sensors to remain in “stand-by” mode, then, the sensors are synchronized with the electronic control unit, and the output signal value generated by the motion sensor and activating working cycle of device, the output signal value generated by the dusk sensor, at which the voltage provided to the light source increases stepwise up to the maximum and the light source emits light with full 100% power, light emission time after which the voltage provided to the light source decreases stepwise and light source does not emit light and device passes into “stand-by” mode, are set-up in the electronic control unit.

After setting-up all the values the device works in automatic cycle, i.e. it remains in “stand-by” mode when the light source does not emit light and the sensors remain in “stand-by”mode. When the motion sensor detects the movement, the electronic control unit compares the signal, generated by the dusk sensor, and checks whether the minimum admissible level of natural lighting has been exceeded—if it is darker, the unit increases light source feeding voltage to the maximum value, and keeps it for the whole pre-set time—the device emits light with full 100% power. After this time, the unit checks whether the motion sensor still generates a detection signal—if so, the feeding is kept at maximum value, if not—the voltage is reduced to the minimum value, and device passes into “stand-by”mode and does not emit light.

A minimal power consumption in “stand-by” mode is a distinctive feature of device (only motion and dusk sensors are fed).

A block diagram of lighting intensity automatic adjustment method, according to the invention, in the next execution example is shown in FIG. 2. It is used in a device with lighting intensity automatic adjustment, containing an electronic control unit, a light source, and a motion sensor. The essence of the method is that after connecting the device to the supply network the parameters of minimum feeding voltage value, allowing the electronic control unit as well as the motion sensor to remain in “stand-by” mode; then, the motion sensor is synchronized with the electronic control unit, and the output signal value generated by the motion sensor and activating working cycle of device, the time of voltage increase, when the voltage provided to the light source increases smoothly within the requested time (f.i. 3 seconds) up to the maximum value, the time of emitting light by the light source with full 100% power, the time of voltage decrease, when the voltage provided to the light source decreases smoothly within the requested time (f.i. 3 seconds) to the minimum value (f.i. 10% of power) and device passes into “stand-by” mode—the light source emits light with f.i. 10% of power, are set-up in the electronic control unit.

After setting-up all the values the device works in automatic cycle, i.e. it remains in “stand-by” mode when the light source emits light with well-defined, minimum power (f.i. 10%) and the motion sensor remains in “stand-by” mode. Then, when the motion sensor detects the movement, the electronic control unit increases smoothly the voltage feeding the light source to the maximum value, and keeps it for the whole pre-set time—the device emits light with full 100% power. After this time, the unit checks whether the motion sensor still generates a detection signal—if so, the feeding is kept at maximum value, if not—the device passes into “stand-by” mode, the voltage is smoothly reduced and the device emits light with well-defined, minimum power.

A block diagram of lighting intensity automatic adjustment method, according to the invention, in another execution example is shown in FIG. 3. The difference between this solution and the solution shown in FIG. 2 consists in this, that the device applying the method, according to invention, has been additionally equipped with a dusk sensor. Thanks to the dusk sensor use, until dusk threshold is not exceeded the device remains in “stand-by” mode—the light source does not emit light. When the dusk threshold is exceeded, the device remains in “stand-by” mode, passing to the limited power consumption mode at the pre-set level, f.i. about 10% of the maximum power—the light source emits light with limited pre-set power (f.i. 10%). If an object appears in the range of motion sensor, the device works as described above, i.e. within the pre-set time (f.i. 3 seconds) the voltage is being smoothly increased to the full power, the light source is smoothly brightening up, emits light with full power and remains in such a mode until the object motion is not detected. Then, the light source grows dark smoothly to the pre-set level of 10% of supplied power. The light source of the device stops emitting light at the moment, when the “brightness threshold” is exceeded (the situation similar to the activation of light source).

A block diagram of lighting intensity automatic adjustment method, according to the invention, in another execution example is shown in FIG. 4. This option enables to prolong the lighting time with minimal consumption of power. The device is not equipped with a dusk sensor, so it is a device operating round the clock. In order to achieve the requested functional results, the device has been equipped with in a time measuring unit, enabling to fix the time, after which the device passes into the appropriate lighting mode: full—100% of power, or limited—f.i. 10% of power. The device is equipped with a motion sensor, which puts it into service when motion is detected within sensor range—the device works in full 100% power lighting mode. After the pre-set time, the device automatically and smoothly passes into limited lighting mode, using ca 10% of the full power—at that moment the device starts measuring time.

If no motion is detected during time countdown (the device works at that time in limited lighting mode), then after f.i. 15 minutes the device is getting switched off and passes into “stand-by” mode. The succeeding detection of motion within the range of sensor will make the light source brighten up to 100% of power and working in full lighting mode, then—if no motion is detected by the sensor—the device returns to the limited power consumption mode, f.i. 10%. The light source emits light with 10% power and, after following f.i. 15 minutes of “no motion”, it is getting switched off, and the device passes into “stand-by” mode. If—while device passes into limited mode of working—the motion is detected, the device will automatically and smoothly return to the full working mode, ensuring 100% of lighting.

The device with lighting intensity automatic adjustment in an advisable execution example is shown in general outline in FIG. 5.

The device with lighting intensity automatic adjustment, according to the invention, contains a feeding converter. The converter clamps are directly connected to to the supply network, and converter itself is composed of the following elements connected in series: perpetual conduction interference filter EMI, rectifier with passive power factor correction system PPFC, reducing distorsions of current absorbed from the supply network, PWM controller of MOSFET power transistor and safety system PWM-MOS, pulse transformer TR, rectifier with an output filter RC and feedback block, stabilizing the output current/output voltage CC/CV—the outputs of which are connected to the light source, f.i. LED, through a galvanic separator of feedback circuit OPTO, to the input of controller of MOSFET power transistor and MOSFET power transistor and safety system PWM-MOS, to the feeder ZKPIR of PR sensor controller, connected with passive infrared sensor PR output, and—through the output current regulator RPW—with feedback block, stabilizing the output current/output voltage CC/CV. The light source is connected to the coupled inputs of the feedback block, stabilizing the output current/output voltage CC/CV, of the rectifier with an output filter RC and of the pulse transformer TR, being interconnected, and though the galvanic separation of feedback circuit OPTO—with MOSFET power transistor PWM controller as well as MOSFET power transistor PWM-MOS.

The function of passive infrared sensor PIR consists in detecting motion of objects being within passive infrared sensor PIR range, and then in providing information about detected object to the output current regulator RPW. The motion is stated by detecting changes in infrared radiation emitted by objects moving in the range of passive infrared sensor PIR, compared with background radiation.

The signal from passive infrared sensor PIR is amplified, and then—processed by controlling module KPIR. The module KPIR controls the switch on of output current regulator, making a smooth lamp brightening within well-defined time. If the movement of objects stops the KPIR controlling module additionally keeps module RPW switched on within precisely programmed time. Then, the RPW modul is switched off, making the lamp darkening to the well-defined power.

The module KPIR is supplied with power by the feeder ZKPIR, which in this model of lamp is directly fed by a converter, feeding LED modules. The function of RPW is to limit smoothly the current passing through LEDs. Thanks to that, the power of the lamp goes down, f.i. to 10% of the maximum value and the lamp works in limited power consumption mode. If, while working in limited power consumption mode, the PIR sensor detects a motion, the RPW unit increases smoothly the current passing through LEDs to the maximum value—the lamp operates with full power.

The lighting intensity automatic adjustment unit in another advisable execution example is shown in general outline in FIG. 6.

The PIR motion sensor is fed sinusoidally from supply network with the alternating current of 230V/50 Hz. The function of PIR motion sensor consists in detecting motion of objects being within PIR sensor range, and then to switch on the load connected to the MPO module (electromagnetic relay of direct current), feeding the light source, f.i. LEDs. The motion is stated by detecting changes in infrared radiation emitted by objects moving in the range of PIR motion sensor, compared with background radiation.

The signal from PIR motion sensor is amplified, and then—processed by controlling module KPIR. The module KPIR controls switching on the module of the load change-over MPO. Switching on the MPO module means, that the 230V/50 Hz current from the supply network is provided to the clamps of the feeding converter, which is composed of connected in series: perpetual conduction interference filter EMI, rectifier with passive power factor correction system PPFC, reducing distorsions of current absorbed from the supply network, PWM controller of MOSFET power transistor together with MOSFET power transistor and safety system PWM-MOS, pulse transformer TR, rectifier with an output filter RC and feedback block, stabilizing the output current/output voltage CC/CV. The outputs of the feedback block are connected with the light source, f.i. LEDs, through a galvanic feedback circuit separator OPTO with the input of PWM controller of MOSFET power transistor together with MOSFET power transistor and with safety system PWM-MOS.

If, after processing signals from PIR detector, the controller KPIR detects the motion, it switches the MPO module, and thus converter module on and keeps them so, until the motion is being detected. When the movement stops, the controller KPIR additionally keeps the MPO module switched on within precisely determined, programmed period of time. After that, the MPO module is being switched off, cutting off the converter's circuit feeding. The KPIR module is supplied with power through the ZKPIR feeder, providing constant voltage of required pre-set parameters to the KPIR controller, and the current has power allowing to control properly the MPO module.

The ZKPIR feeder is designed and made in the way allowing to achieve its high watt-hour efficiency, both in “stand-by” (no movement in the range of PR motion sensor; the MPO module switched off) and switching the load (the MPO module switched on) modes. The efficiency of ZKPIR feeder is switched over the work in “stand-by” mode, characterized by a limited power consumption resulting from the fact, that it is consumed by KPIR controller's circuit only, and in “working with load” mode, enabling to supply the MPO module (relay coil) with power allowing to switch on the converter. The ZKPIR feeder's switch-over from “stand-by” mode into “working with load” mode is effected by closing/opening additional pair of MPO module contacts.

The lamp is additionally equipped with an automatic control of work, operating as follows: at the moment, when no movement is detected by PIR motion sensor, the KPIR controller transmits a signal to UOC time measuring unit, which start counting down the time. After the pre-set time, the UOC time measuring unit transmit the information about this fact to the RPW output current regulator. The function of the RPW output current regulator consists in reducing smoothly the current passing through the light source, f.i. through LEDs. Thanks to that the lamp power goes down to 10% of the maximum value, and the lamp works in limited power consumption mode. If, while working in limited power consumption mode, the PIR motion sensor detects a movement, the time countdown is reset, and the RPW unit increases smoothly the current passing through the light source to the maximum value—the lamp works with full power. If, while working in limited power consumption mode, the PIR motion sensor has not detected any movement, and the UOC time measuring unit has measured the time pre-set by the user, the UOC time measuring unit transmits the signal to the MPO module, which disconnect the network voltage from the converter, and the lamp starts working in “stand-by” mode.

The lighting intensity automatic adjustment unit in another, successive advisable execution example is shown in general outline in FIG. 7. The difference between this solution and the solution shown in FIG. 6 consists in this, that the device is additionally equipped with a CZ dusk sensor, connected directly to the input of KPIR controller of the passive infrared sensor. The function of this dusk sensor is to block lamp switching on, when the daylight intensity in the environment is big enough to not use the artificial light, so the lamp will operate only when it gets dark. The signal about lighting intensity coming from the CZ dusk sensor is always processed by KPIR controller, and in case, when switching on the artificial lighting is not necessary, the controller—in spite of signal received from PIR motion sensor—does not switch the MPO module on and does not activate the RPW output current regulator. The device works in “stand-by” mode until conditions of external lighting change.

It is obvious, that constructional solutions presented above are taken by the way of example and do not impose restrictions on the essence of invention. 

1. The method of lighting intensity automatic adjustment, characterized in that after connecting device to supply network, the minimum value of feeding voltage parameters, allowing the electronic control system as well as motion and dusk sensors to remain in “stand-by” mode, is set-up, then, sensors are synchronized with electronic control system, both—value of output signal generated by motion sensor and activating cycle of device's working mode, and value of output signal generated by dusk sensor at which the voltage provided to the light source increases to its maximum value—are set-up in the electronic system, and during programmed lighting time the light source emits light with full 100% power, time of light emitting and voltage decrease time, in which voltage provided to the light source decreases smoothly to the minimum power value—are also set-up in the electronic system—the light source does not emit light and the device passes into “stand-by” mode, therefore after setting-up all values, the device is left in “stand-by” mode and sensors remain in “stand-by” mode too, further device is activated automatically when a movement is detected by the motion sensor and its signal is transmitted to the unit, which compares signal generated by the motion sensor with signal generated by dusk sensor, as well as with value being previously set-up, i.e. it checks whether the minimum admissible natural lighting level is exceeded or not—if it is darker, the system increases voltage of light source feeding to the maximum value—the device emits light with full 100% power and keeps it within the pre-set period of time, then after this pre-set period of time expired the system checks whether the motion sensor still generates a detection signal, if so—voltage provided to the light source is kept at its maximum level, if not—voltage provided to the light source is reduced to its minimum value, and the device passes into “stand-by” mode—the device does not emit light.
 2. The method according to the claim 1, characterized in that the voltage provided to the light source increases to the maximum value—the light source emits light with full 100% power, or decreases stepwise.
 3. The method according to the claim 1, characterized in that the voltage provided to the light source increases to the maximum value—the light source emits light with full 100% power, or decreases smoothly.
 4. The method of lighting intensity automatic adjustment, characterized in that after connecting device to supply network, the minimum value of feeding voltage parameters, allowing the electronic control system as well as the motion sensor to remain in “stand-by” mode is set-up, then, the motion sensor is synchronized with electronic control system, the value of output signal generated by motion sensor and activating working cycle mode of device, time of voltage increase, in which voltage provided to the light source increases smoothly to the maximum value within a pre-set time, time of emitting light by the light source with full 100% power, time of voltage decrease, in which voltage provided to the light source decreases smoothly to the minimum power value within a pre-set time are also set-up in the control system, the device passes into “stand-by”mode, the light source emits light with minimum power, therefore after setting-up all data, the device is left in “stand-by” mode—the light source emits light with well-defined minimum power, and the motion sensor remains in “stand-by” mode; then, when a movement is detected by the motion sensor, the system increases smoothly the voltage of light source feeding to the maximum value—the device emits light with full 100% power and keeps it within the pre-set period of time, then after this the pre-set period of time expired the system checks whether the motion sensor still generates a detection signal, if so—voltage provided to the light source is kept at its maximum level, if not—the device passes into the “stand-by” mode, voltage is reduced smoothly—the device emits light with well-defined minimum power.
 5. The method according to the claim 4, characterized in that the device is additionally equipped with a dusk sensor and therefore the additional data about required minimum lighting intensity of environment are set-up in the electronic system, and below this level the device passes from “stand-by” to working mode, and when a movement is detected the respective signal is transmitted by the motion sensor, the lighting intensity of environment is measured, the signal coming from the dusk sensor is compared with the value pre-set for device activation and transmission of signals switching on or off the light source feeding.
 6. The method according to the claim 4, characterized in that the device is additionally equipped with a time measuring unit, which is synchronized with motion sensor and electronic control system, the additional value, i.e. time of working in reduced power mode is set-up in the electronic system; after terminating working with full power, the light source emits lights with a limited power—following signal coming from the motion sensor, and it waits for further motion sensor's signal—in case of its lack, the device passes into the “stand-by” mode, in case the signal is transmitted—into 100% working mode.
 7. The device with lighting intensity automatic adjustment, characterized in that containing a feeding converter having clamps directly connected to the supply network, composed of the following elements, connected in series (EMI) perpetual conduction interference filter, rectifier with passive power factor correction system (PPFC), reducing distorsions of current absorbed from the supply network, PWM controller of MOSFET together with MOSFET power transistor and PWM-MOS safety system, pulse transformer (TR), rectifier with an output filter (RC) and feedback block, stabilizing the output current/output voltage (CC/CV), the feedback block outputs are connected to the light source—LEDs, through a galvanic separator of feedback circuit (OPTO), to the input of PWM controller of MOSFET power transistor and MOSFET power transistor (PWM-MOS) as well as to the feeder (ZKPIR) of motion sensor controller (KPIR), connected to the motion sensor (PIR) output, and—through the output current regulator (RPW)—to the feedback block, stabilizing the output current/output voltage (CC/CV) of rectifier with an output filter (RC) and pulse transformer (TR), which are interconnected, and—through the galvanic separation of feedback circuit (OPTO)—to the MOSFET power transistor PWM controller as well as to MOSFET power transistor and safety system (PWM-MOS), whilst the assignment of motion sensor (PR) consist in detecting movement of objects within motion sensor (PIR) range and then to transmit information about detected object to the output current regulator (RPW), which signal from the passive infrared sensor (PIR) is amplified, and then, it is processed by the sensor controller (KPIR), controlling the output current switch output current regulator (RPW), which allows a smooth brightening of the light source within the required, pre-set time, and when the movement stops, the controller (KPIR) additionally keeps the output current regulator (RPW) switched on within precisely determined, programmed period of time, and after that, the output current regulator (RPW) is being switched off, turning the lights down to the well-defined power, the power provided to the controller (KPIR) is realized through the feeder (ZKPIR), supplied directly from the converter, feeding the light source, and the output current regulator (RPW) function consists in reducing smoothly the current passing through the light source, so that the power decreases and system works in limited power consumption mode, or in increasing smoothly the current passing through the light source, to the maximum value.
 8. The device with lighting intensity automatic adjustment, characterized in that contain a motion sensor (PIR) fed with supply network power, the function of which consists in detecting movement of objects being within the range of the motion sensor (PIR), and then to switch on the load connected to the module (MPO) of the light source feeder, which signal generated by motion sensor (PIR) is amplified, and then it is processed by controller (KPIR) controlling switching on the module of the load change-over (MPO), said switching on this module (MPO) means, that voltage from supply network is provided to the clamps of feeding converter, which is composed of perpetual conduction interference filter (EMI), rectifier with passive power factor correction system (PPFC), reducing distorsions of current absorbed from supply network, PWM controller of MOSFET power transistor together with MOSFET power transistor and safety system (PWM-MOS), pulse transformer (TR), rectifier with an output filter (RC) and feedback block, stabilizing the output current/output voltage (CC/CV)—all this elements connected in series, in case, if the controller (KPIR), basing on signals received from sensor's detector (PIR) discovers a motion switched on the module (MPO)—and thus, the converter—and remains so, until motion is being detected, in case the motion stops, the controller (KPIR) additionally keeps the module (MPO) switched on within precisely determined, programmed period of time and after that, the module (MPO) is being switched off, cutting off supply of the converter's circuit, whilst the module (KPIR) is supplied with power through the feeder (ZKPIR) providing constant voltage of required pre-set parameters to the controller (KPIR) and the current has power level, allowing to proper control of the module (MPO), and is equipped with a time measuring unit (UOC), connected to the controller (KPIR), said controller (KPIR) if no motion is detected by the motion sensor (PIR), transmits a signal to the time measuring unit (UOC), which begins to count down the time, and after a pre-set period, time measuring unit (UOC) transmits such information to the output of current regulator (RPW), which reduces smoothly the current passing through the light source, and thanks to that, the device works in limited power consumption mode, whilst during working in this mode—the motion sensor (PIR) detects a movement, the time measuring is reset, and output current regulator (RPW) increases smoothly the current passing through the light source to the maximum value, while in case when no movement is detected by motion sensor (PIR) working in limited power consumption mode and the pre-set time is counted down, the time measuring unit (UOC) transmits the respective signal to the module (MPO), which disconnects network voltage from converter and all remaining units start working in “stand-by”mode.
 9. The device according to the claim 8, characterized in that it is equipped with a dusk sensor (CZ), connected directly to controller's (KPIR) input, which function of consists in detecting the environment day-light intensity within the range of the dusk sensor (CZ), when the light intensity is insufficient and switching on the artificial lighting is necessary, and then—in transmitting such information to the controller (KPIR) in which the information is processed and compared with the required, pre-set value and then, the module (MPO)—and thus, the converter—is switched on by the controller (KPIR) and remains so, until the motion is being detected and light intensity remains insufficient, or—it is switched off and remains so, when the light intensity is too big. 